As society attaches the importance to the application of renewable energy, the research of thermoelectric materials has received much more attention. In contrast to the traditional inorganic and organic material, which have made a huge improvement in thermoelectric field over the past decades, two-dimensional materials provide a new direction for the thermoelectric materials development because of their unique of layered structure and the diversity of material. Furthermore, by enhancing the phonon scattering probability, two-dimensional materials can reduce the thermal conductivity and maintain the electrical conductivity which result in not only a better performance but also an advantage in designing and improving the thermoelectric devices. However, due to the thickness of two-dimensional materials is much smaller than the three-dimensional materials, many traditional measurements methodology designs for three-dimensional materials are not suitable for two-dimensional materials owing to some difficulty in experimental setup or low sensitivity to in-plane heat transportation. Until now, there is still a lack of universal standards to accurately measure two-dimensional materials. In recent years, many scientists have developed some measurements and techniques for two-dimensional materials. In this article, we will mainly introduce the advantages of two-dimensional materials in the thermoelectric devices and review these applicable two-dimensional measurement methods. We believe that it will help to determine the thermoelectric performance (ZT) of two-dimensional materials and develop the future of thermoelectrics.